Positive solutions to boundary value problems of fractional difference equation with nonlocal conditions

In this paper, we will use the Krasnosel’skii fixed point theorem to investigate a discrete fractional boundary value problem of the form $-{\mathrm{\Delta }}^{\nu }y(t)=\lambda h(t+\nu -1)f(y(t+\nu -1))$, $y(\nu -2)=\mathrm{\Psi }(y)$, $y(\nu +b)=\mathrm{\Phi }(y)$, where $1<\nu ⩽2$, $t\in {[0,b]}_{{\mathbb{N}}_0}$, $f:[0,\mathrm{\infty })\to [0,\mathrm{\infty })$ is a continuous function, $h:{[\nu -1,\nu +b-1]}_{{\mathbb{N}}_{\nu -1}}\to [0,\mathrm{\infty })$, $\mathrm{\Psi },\mathrm{\Phi }:{\mathbb{R}}^{b+3}\to \mathbb{R}$ are given functionals, where Ψ, Φ are linear functionals, and λ is a positive parameter.

MSC:26A33, 39A05, 39A12.

The theory of fractional differential equations and their applications has received intensive attention. However, the theory of fraction difference equations is still limited. But in the last few years, a number of papers on fractional difference equations have appeared [1–13]. Among them, Atici and Eloe [1] introduced and developed properties of discrete fractional calculus. In [2], Atici and Eloe studied a two-point boundary valve problem for a finite fractional difference equation. They obtained sufficient conditions for the existence of solutions for the following boundary value problem:

where $t\in {[0,b+1]}_{{\mathbb{N}}_0}$, $1<\nu ⩽2$, and $f:{[\nu -1,\nu +b]}_{{\mathbb{N}}_{\nu -1}}\times \mathbb{R}\to \mathbb{R}$ is a continuous function. Goodrich [3] deduced uniqueness theorems by means of the Lipschitz condition and deduced the existence of one or more positive solutions by using the cone theoretic techniques for this same boundary value problem. He showed that many of the classical existence and uniqueness theorems for second-order discrete boundary value problems extend to the fraction-order case. In [4], Goodrich obtained the existence of positive solutions to another boundary value problem. Goodrich [5] also considered a pair of discrete fractional boundary value problem of the form

where $t\in {[0,b]}_{{\mathbb{N}}_0}$, ${\lambda }_i>0$, $a_i:\mathbb{R}\to [0,\mathrm{\infty })$, ${\nu }_i\in (1,2]$ for each $i=1,2$. ${\mathrm{\Psi }}_i,{\mathrm{\Phi }}_i:{\mathbb{R}}^{b+3}\to \mathbb{R}$ are given functionals, and $f_i:[0,\mathrm{\infty })\times [0,\mathrm{\infty })\to [0,\mathrm{\infty })$ is continuous for each admissible i.

Extensive literature exists on boundary value problems of fractional difference equations [9–13]. Ferreiraa [9] provided sufficient conditions for the existence and uniqueness of solution to some discrete fractional boundary value problems of order less than 1. Goodrich [11–13] studied a ν order ($1<\nu ⩽2$) discrete fractional three-point boundary value problem and semipositone discrete fractional boundary value problems.

In this paper, we consider the following boundary value problems of fractional difference equation with nonlocal conditions:

where $t\in {[0,b]}_{{\mathbb{N}}_0}$, $1<\nu ⩽2$, $f:[0,\mathrm{\infty })\to [0,\mathrm{\infty })$ is a continuous function. $h:{[\nu -1,\nu +b-1]}_{{\mathbb{N}}_{\nu -1}}\to [0,\mathrm{\infty })$, $\mathrm{\Psi },\mathrm{\Phi }:{\mathbb{R}}^{b+3}\to \mathbb{R}$ are given linear functionals and λ is a positive parameter. The boundary conditions (2)-(3) are generally called nonlocal conditions. Our analysis relies on the Krasnosel’kill fixed-point theorem to get the main results of problem (1)-(3).

The paper will be organized as follows. In Section 2, we will present basic definitions and demonstrate some lemmas in order to prove our main results. In Section 3, we establish some results for the existence of solutions to problem (1)-(3), and we provide an example to illustrate our main results.

Let us first recall some basic lemmas which plays an important role in our discussions.

Definition 2.1 [1]

We define

for any t and ν for which the right-hand side is defined. We also appeal to the convention that if $t+1-\nu$ is a pole of the Gamma function and $t+1$ is not a pole, then $t^{(\nu )}=0$.

Definition 2.2 [1]

The ν th fractional sum of a function f defined on the set ${\mathbb{N}}_a:=\{a,a+1,\dots \}$, for $\nu >0$, is defined to be

where $t\in \{a+\nu ,a+\nu +1,\dots \}=:{\mathbb{N}}_{a+\nu }$. We also define the ν th fractional difference, where $\nu >0$ and $0⩽N-1<\nu ⩽N$, to be

where $t\in {\mathbb{N}}_{a+\nu }$.

Lemma 2.1 [1]

Let t and ν be any numbers for which $t^{(\nu )}$ and $t^{(\nu -1)}$ are defined. Then

Lemma 2.2 [1]

Let $0⩽N-1<\nu ⩽N$. Then

for some $c_i\in \mathbb{R}$, with $1⩽i⩽N$.

Lemma 2.3 [4]

Let $1<\nu ⩽2$, and $h:{[\nu -1,\nu +b-1]}_{{\mathbb{N}}_{\nu -1}}\to \mathbb{R}$ be given. The unique solution of the FBVP

is given by

where $G:{[\nu -2,\nu +b]}_{{\mathbb{N}}_{\nu -2}}\times {[0,b]}_{{\mathbb{N}}_0}\to \mathbb{R}$ is defined by

Lemma 2.4 [4]

The Green function $G(t,s)$ given in Lemma 2.3 satisfies:

1. (i)

   $G(t,s)⩾0$, for each $(t,s)\in {[\nu -2,\nu +b]}_{{\mathbb{N}}_{\nu -2}}\times {[0,b]}_{{\mathbb{N}}_0}$;

2. (ii)

   ${max}_{t\in {[\nu -2,\nu +b]}_{{\mathbb{N}}_{\nu -2}}}G(t,s)=G(s+\nu -1,s)$ for each $s\in {[0,b]}_{{\mathbb{N}}_0}$; and

3. (iii)

   there exists a number $\gamma \in (0,1)$ such that

   $$\underset{\frac{\nu +b}{4}⩽t⩽\frac{3(\nu +b)}{4}}{min}G(t,s)⩾\gamma \underset{t\in {[\nu -2,\nu +b]}_{{\mathbb{N}}_{\nu -2}}}{max}G(t,s)=\gamma G(s+\nu -1,s),$$

   for $s\in {[0,b]}_{{\mathbb{N}}_0}$.

Theorem 2.1 Let $f:[0,\mathrm{\infty })\to [0,\mathrm{\infty })$, and $\mathrm{\Psi },\mathrm{\Phi }\in C({[\nu -2,\nu +b]}_{{\mathbb{N}}_{\nu -2}},\mathbb{R})$ be given. A function $y(t)$ is a solution of the discrete FBVP (1)-(3) if and only if $y(t)$ is a fixed point of the operator

where

and $G(t,s)$ is as given in Lemma 2.3.

Proof From Lemma 2.2, we find that a general solution to problem (1)-(3) is

From the boundary condition (2), we get

so

On the other hand, applying the boundary condition (3) to $y(t)$ implies that

Namely

so

Finally, we get

Consequently, we see that $y(t)$ is a solution of (1)-(3) if and only if $y(t)$ is a fixed point of (5), as desired. □

Lemma 2.5 The function $\alpha (t)$ is strictly decreasing in t, for $t\in {[\nu -2,\nu +b]}_{{\mathbb{N}}_{\nu -2}}$. In addition, ${min}_{t\in {[\nu -2,\nu +b]}_{{\mathbb{N}}_{\nu -2}}}\alpha (t)=0$, and ${max}_{t\in {[\nu -2,\nu +b]}_{{\mathbb{N}}_{\nu -2}}}\alpha (t)=1$. On the other hand, the function $\beta (t)$ is strictly increasing in t, for $t\in {[\nu -2,\nu +b]}_{{\mathbb{N}}_{\nu -2}}$. In addition, ${min}_{t\in {[\nu -2,\nu +b]}_{{\mathbb{N}}_{\nu -2}}}\beta (t)=0$, and ${max}_{t\in {[\nu -2,\nu +b]}_{{\mathbb{N}}_{\nu -2}}}\beta (t)=1$.

Proof Note that for every $t\in {[\nu -2,\nu +b]}_{{\mathbb{N}}_{\nu -2}}$,

So, the first claim about $\alpha (t)$ holds. On the other hand,

It follows that

In a similar way, it may be shown that $\beta (t)$ satisfies the properties given in the statement of this lemma. We omit the details. □

Corollary 2.1 Let $I=[\frac{b+\nu }{4},\frac{3(b+\nu )}{4}]$. There are constants $M_{\alpha },M_{\beta }\in (0,1)$ such that ${min}_{t\in I}\alpha (t)=M_{\alpha }\parallel \alpha \parallel$, ${min}_{t\in I}\beta (t)=M_{\beta }\parallel \beta \parallel$, where $\parallel \cdot \parallel$ is the usual maximum norm.

Lemma 2.6 [14]

Let E be a Banach space, and let $\mathcal{K}\subset E$ be a cone in E. Assume the bounded sets ${\mathrm{\Omega }}_1$, ${\mathrm{\Omega }}_2$ are open subsets of E with $0\in {\mathrm{\Omega }}_1\subset {\overline{\mathrm{\Omega }}}_1\subset {\mathrm{\Omega }}_2$, and let

be a completely continuous operator such that either

1. (1)

   $\parallel Su\parallel ⩽\parallel u\parallel$, $u\in \mathcal{K}\cap \partial {\mathrm{\Omega }}_1$, $\parallel Su\parallel ⩾\parallel u\parallel$, $u\in \mathcal{K}\cap \partial {\mathrm{\Omega }}_2$; or

2. (2)

   $\parallel Su\parallel ⩾\parallel u\parallel$, $u\in K\cap \partial {\mathrm{\Omega }}_1$, $\parallel Su\parallel ⩽\parallel u\parallel$, $u\in K\cap \partial {\mathrm{\Omega }}_2$.

Then S has a fixed point in $\mathcal{K}\cap ({\overline{\mathrm{\Omega }}}_2\setminus {\mathrm{\Omega }}_1)$.

In the sequel, we let

where γ is the number given in Lemma 2.4(iii). Observe that $\tilde{\gamma }\in (0,1)$. We now present the conditions on Ψ, Φ, and f that we presume in the sequel:

• (S1) ${lim}_{y\to 0}\frac{f(y)}{y}=\mathrm{\infty }$, ${lim}_{y\to \mathrm{\infty }}\frac{f(y)}{y}=\mathrm{\infty }$.

• (S2) ${lim}_{y\to 0}\frac{f(y)}{y}=0$, ${lim}_{y\to \mathrm{\infty }}\frac{f(y)}{y}=0$.

• (S3) ${lim}_{y\to 0}\frac{f(y)}{y}=l$, $0<l<\mathrm{\infty }$.

• (S4) ${lim}_{y\to \mathrm{\infty }}\frac{f(y)}{y}=L$, $0<L<\mathrm{\infty }$.

• (G1) The functionals Ψ, Φ are linear. In particular, we assume that

  $$\mathrm{\Psi }(y)=\sum _{i=\nu -2}^{\nu +b}{c}_{i-\nu +2}y(i),\mathrm{\Phi }(y)=\sum _{k=\nu -2}^{\nu +b}{d}_{k-\nu +2}y(k),$$

  for $c_{i-\nu +2},d_{k-\nu +2}\in \mathbb{R}$.

• (G2) We have both ${\sum }_{i=\nu -2}^{\nu +b}{c}_{i-\nu +2}G(i,s)⩾0$ and ${\sum }_{k=\nu -2}^{\nu +b}{d}_{k-\nu +2}G(k,s)⩾0$, for each $s\in {[0,b]}_{{\mathbb{N}}_0}$, and

  $$\sum _{i=\nu -2}^{\nu +b}{c}_{i-\nu +2}+\sum _{k=\nu -2}^{\nu +b}{d}_{k-\nu +2}⩽\frac{1}{2}.$$

• (G3) Each of $\mathrm{\Psi }(\alpha )$, $\mathrm{\Psi }(\beta )$, $\mathrm{\Phi }(\alpha )$, $\mathrm{\Phi }(\beta )$ is nonnegative.

First, we let ℬ represent all maps from ${[\nu -2,{\nu }_{+}b]}_{{\mathbb{N}}_{\nu -2}}$ into ℝ, and equipped with the maximum norm $\parallel \cdot \parallel$. Clearly, ℬ is a Banach space. We define the cone $\mathcal{K}\subset \mathcal{B}$ by

Lemma 3.1 Assume that (G1)-(G3) hold, and let T be the operator defined in (5). Then $T:\mathcal{K}\to \mathcal{K}$.

Proof For every $y\in \mathcal{K}$, by (G1), we show first that

By assumptions (G2) and (G3) together with the nonnegativity of $f(y)$ and the fact that $y\in \mathcal{K}$, we can get $\mathrm{\Psi }(Ty)⩾0$:

It also shows that $\mathrm{\Phi }(Ty)⩾0$.

On the other hand, it follows from both Lemma 2.4 and Corollary 2.1 that

Hence

Finally, for every $y\in \mathcal{K}$,

So, we conclude that $T:\mathcal{K}\to \mathcal{K}$, and the proof is complete. □

Lemma 3.2 Suppose that conditions (G1)-(G3) hold, and there exist two different positive numbers a, b such that

Then, problem (1)-(3) has at least one positive solution $\overline{y}\in \mathcal{K}$ such that $min\{a,b\}⩽\parallel \overline{y}\parallel ⩽max\{a,b\}$.

Proof Let ${\mathrm{\Omega }}_a:=\{y\in \mathcal{K}:\parallel y\parallel <a\}$. Then, for any $y\in \mathcal{K}\cap \partial {\mathrm{\Omega }}_a$, we have

that is, $\parallel Ty\parallel ⩽\parallel y\parallel$ for $y\in \partial {\mathrm{\Omega }}_a\cap \mathcal{K}$.

On the other hand, we let ${\mathrm{\Omega }}_b:=\{y\in \mathcal{K}:\parallel y\parallel <b\}$. For any $y\in \mathcal{K}\cap \partial {\mathrm{\Omega }}_b$, we have

that is, $\parallel Ty\parallel ⩾\parallel y\parallel$ for $y\in \mathcal{K}\cap \partial {\mathrm{\Omega }}_b$. By means of Lemma 2.6, there exists $\overline{y}\in \mathcal{K}$ such that $T\overline{y}=\overline{y}$. □

Theorem 3.1 Suppose that conditions (S1), and (G1)-(G3) hold. Then, for every $\lambda \in (0,{\lambda }^{\ast })$, problem (1)-(3) has at least two positive solutions, where

Proof Define function $q(r)=\frac{r}{\sigma {max}_{0⩽y⩽r}f(y)}$. In view of the continuity of the function $f(y)$, we have $q(r)\in C((0,\mathrm{\infty }),(0,\mathrm{\infty }))$. From ${lim}_{y\to 0}\frac{f(y)}{y}=\mathrm{\infty }$, we see that ${lim}_{r\to 0}\frac{r}{\sigma f(r)}=0$, that is,

so

By ${lim}_{y\to \mathrm{\infty }}\frac{f(y)}{y}=\mathrm{\infty }$, we see further that ${lim}_{r\to \mathrm{\infty }}q(r)=0$. Thus, there exists $r_0>0$ such that $q(r_0)={max}_{r>0}q(r)={\lambda }^{\ast }$. For any $\lambda \in (0,{\lambda }^{\ast })$, by means of the intermediate value theorem, there exist two points $l_1$, $l_2$ ($0<l_1<r_0<l_2<\mathrm{\infty }$) such that $q(l_1)=q(l_2)=\lambda$. Thus, we have

On the other hand, in view of (S1), we see that there exist $d_1$, $d_2$ ($0<d_1<l_1<r_0<l_2<d_2<\mathrm{\infty }$) such that

That is,

An application of Lemma 3.2 leads to two distinct solutions of (1)-(3) which satisfy $d_1⩽\parallel \overline{y_1}\parallel ⩽l_1,l_2⩽\parallel \overline{y_2}\parallel ⩽d_2$. □

Theorem 3.2 Suppose (S2) and (G1)-(G3) hold. Then for any $\lambda >{\lambda }^{\ast \ast }$, equations (1)-(3) have at least two positive solutions. Here

The proof is similar to Theorem 3.1 and hence is omitted.

Theorem 3.3 Assume that (S3), (S4) and (G1)-(G3) hold. For each λ satisfying

or

equations (1)-(3) have a positive solution.

Proof Suppose (16) holds. Let $\eta >0$ be such that

Note that $l>0$. There exists $H_1>0$ such that $f(y)⩽(l+\eta )y$ for $0<y⩽H_1$. So, for $y\in \mathcal{K}$ and $\parallel y\parallel =H_1$, we have

That is, $\parallel Ty\parallel \le \parallel y\parallel$ for $y\in \mathcal{K}$ and $\parallel y\parallel =H_1$.

Next, since $L>0$, there exists a ${\overline{H}}_2>0$ such that $f(y)⩾(L-\eta )y$ for $y⩾\tilde{\gamma }{\overline{H}}_2$. Let $H_2=max\{2H_1,{\overline{H}}_2\}$. Then, for $y\in \mathcal{K}$ with $\parallel y\parallel =H_2$,

that is, $\parallel Ty\parallel ⩾\parallel y\parallel$ for $y\in \mathcal{K}$ and $\parallel y\parallel =H_2$.

In view of Lemma 2.6, we see that equations (1)-(3) have a positive solution. The other case is similarly proved. □

Example 3.1 Consider the following boundary value problems:

where $b=20$, $\nu =\frac{13}{10}$, and we take